RU208346U1 - High-voltage source of static voltage for the image intensifier - Google Patents

Abstract

The technical solution relates to the field of electronics and electronic engineering, namely to a high-voltage voltage source for an image intensifier tube, which is part of night vision devices. A high-voltage source of static voltage for an image intensifier tube includes a generator, the output of which is connected to the primary winding of the transformer, a rectifier with a microchannel plate voltage multiplication connected to a voltage control controller, including an output for connecting to the output of the microchannel plate of the image intensifier tube, a rectifier with multiplication screen voltage, connected to the automatic brightness control circuit, including an output for connection to the screen output of the image converter, and a photocathode voltage multiplying rectifier, configured to be connected to the photocathode output of the image converter. According to the claimed technical solution, the transformer is made on the basis of one secondary winding, the output of which is connected to the inputs of the rectifiers with the voltage multiplication of the microchannel plate, the photocathode and the screen, the rectifier with the voltage multiplication of the microchannel plate is connected to the controller to control the voltage through an optocoupler, while to the controller to control voltage is connected to the outputs of the variable resistor, the rectifier with photocathode voltage multiplication is made with the possibility of adjustment, while an isolation capacitor connected to the secondary winding of the transformer is connected to the input of the rectifier with photocathode voltage multiplication, and the output is connected to a voltage divider, which includes a resistor and an adjusting element, and through the protection circuit from bright sources to the output of the photocathode of the electron-optical converter. The technical result is manifested in increasing the reliability of the electron-optical converter.

Description

The technical solution relates to the field of electronics and electronic engineering, namely, to a high-voltage voltage source for an image intensifier, which is a part of night vision devices.

A pulse image converter is known from the prior art comprises a key unit including a first voltage converter, a first microcontroller, a second voltage converter, a pulse shaper; a power supply unit including a second microcontroller, an analog-to-digital converter, the first and second digital-to-analog converters, an amplifier, a microchannel plate amplifier, a screen amplifier, a microchannel plate multiplier, a screen multiplier, a photocathode multiplier; a vacuum unit including a screen, a microchannel plate and a photocathode. RF patent No. 2521599, IPC: H01J 31/50, published on July 10, 2014.

Known technical solution, selected as the closest analogue, representing a power source containing a converter connected to the primary winding of the transformer. The first inputs of the screen voltage multipliers and the microchannel plate are connected to the high-potential output of the secondary winding, and the low-potential output of the secondary winding is connected to the common bus of the power source. The shield voltage multiplier output is connected to the shield. The output of the voltage multiplier of the microchannel plate is connected to the output of the microchannel plate. The input of the microchannel plate is connected to the common bus of the power supply. The negative voltage multiplier of the photocathode is connected by the first input to the high-potential output of the secondary winding, the positive voltage multiplier of the photocathode is connected by the first input to the high-potential output of the secondary winding. The second low-potential outputs of the secondary windings, as well as the second inputs of the voltage multipliers are connected to the common bus of the power supply. The outputs of the voltage multipliers are connected to the inputs of the photocathode switch, the output of which is connected to the photocathode. The input of the automatic brightness control controller is connected to the second, low-voltage input of the screen voltage multiplier. The second output of the automatic brightness control controller is connected to the second input of the operating cycle controller, the first input of which is connected to the output of the master oscillator. The switch input of the microchannel plate is connected to the second output of the duty cycle controller. The output of the switch of the microchannel plate is connected to the second input of the voltage multiplier of the microchannel plate. The first input of the feedback signal of the microchannel plate switch is connected to the first output of the automatic brightness control controller, and the second input of the feedback signal is connected to the output of the feedback amplifier of the microchannel plate, the input of which is connected to the output of the microchannel plate and the output of the voltage multiplier of the microchannel plate. RF patent No. 2346353, IPC: H01J 31/50, published on 10.02.2009.

Distinctive features of the proposed solution are: execution of a transformer based on one secondary winding, to the output of which the rectifier inputs are connected with voltage multiplication of the microchannel plate, photocathode and screen, connection of the rectifier with voltage multiplication of the microchannel plate to the controller for voltage control through an optocoupler, connection of the terminals of a variable resistor to controller for voltage control, connecting a blocking capacitor to the input of the rectifier with multiplying the voltage of the photocathode, connecting the output of the rectifier with multiplying the voltage of the photocathode to a voltage divider, which includes a resistor and an adjusting element, and through a protection circuit against bright sources to the output of the photocathode of the image converter.

The technical result of the proposed technical solution is manifested in increasing the reliability of the image intensifier.

The technical result is achieved by the fact that in a high-voltage source of static voltage for an electro-optical converter, including a generator, the output of which is connected to the primary winding of the transformer, a rectifier with voltage multiplication of the microchannel plate, connected to a controller for voltage control, including an output for connection to the output of the microchannel plate an image converter, a screen voltage multiplier rectifier connected to an automatic brightness control circuit, including an output for connection to the screen output of an image converter, and a photocathode voltage multiplying rectifier configured to be connected to the photocathode output of an optical converter, a transformer made on the basis of one secondary winding, to the output of which the inputs of the rectifiers are connected with the voltage multiplication of the microchannel plate, the photocathode and the screen, the rectifier with the voltage multiplication of the microchannel the output plate is connected to the controller to control the voltage through an optocoupler, while the terminals of the variable resistor are connected to the controller for voltage control, the rectifier with voltage multiplication of the photocathode is adjustable, while an isolation capacitor connected to the secondary winding is connected to the input of the rectifier with voltage multiplication of the photocathode transformer, and the output is connected to a voltage divider, which includes a resistor and an adjusting element, and through the protection circuit from bright sources to the output of the photocathode of the electron-optical converter.

The use of one transformer with one secondary winding in a high-voltage source of static voltage makes it possible to ensure the reliability of the electro-optical converter by reducing the turn-to-turn potentials in the transformer coil, and also makes it possible to introduce automated processes in assembly operations.

Connecting the rectifier with voltage multiplication of the microchannel plate to the controller for voltage control through the optocoupler allows the microchannel plate voltage to be adjusted independently of other channels of the high-voltage source. The independent adjustment of the photocathode voltage is possible by connecting the output of the rectifier with multiplying the voltage of the photocathode to a voltage divider, which includes a resistor and an adjusting element, and, through a protection circuit against bright sources, to the output of the photocathode. Independent adjustment of the electron-optical converter components contributes to an increase in its reliability, in particular, due to the possibility of performing the optimal adjustment of the image-converter, with the best amplification and resolution characteristics, under conditions of mass production, by eliminating discharges and other negative effects in the input the gap of the vacuum tube of the image intensifier.

Connecting a variable resistor to the controller for voltage control is necessary to fine-tune the parameters of the current in the electrical circuit, which is necessary for the reliable operation of the image intensifier.

The claimed technical solution is further illustrated with the help of figure 1, which conventionally shows a diagram of one of the possible versions of a high-voltage source of static voltage for an electro-optical converter, including:

- generator (1);

- transformer (2);

- rectifier (3) with voltage multiplication of the microchannel plate (VUN_M);

- rectifier (4) with photocathode voltage multiplication (VUN_F);

- rectifier (5) with screen voltage multiplication (VUN_E);

- controller (6) for voltage control;

- optocoupler (7);

- circuit (8) automatic brightness control (ARA);

- adjusting element (9);

- scheme (10) for protection from bright sources (BLS);

- resistor (11);

- decoupling capacitor (12) Cp;

- resistor (13) voltage divider;

- resistor (14) of the bias current Rcm;

- trimmer resistor (15) of the photocathode Rf.

Next, the structure of a high-voltage static voltage source for an image intensifier is described with reference to the figure.

The high-voltage source of static voltage for the image intensifier includes a generator (1), the output of which is connected to the primary winding of the transformer (2). The transformer (2) is made on the basis of one secondary winding, to the output of which the inputs of the rectifiers (3, 4, 5) are connected with multiplying the voltage of the microchannel plate, photocathode and screen, respectively.

The rectifier (3) with voltage multiplication of the microchannel plate is connected to the controller (6) to control the voltage through the optocoupler (7) and includes an output for connecting to the output of the microchannel plate of the image converter.

The rectifier (5) with the screen voltage multiplication is connected to the automatic brightness control circuit (8) and turns on the output for connection to the screen output of the electro-optical converter.

The rectifier (4) with multiplying the voltage of the photocathode is made with the possibility of adjusting and connecting to the output of the photocathode of the electro-optical converter. The voltage regulation of the photocathode can be regulated using a high voltage bipolar transistor connected in a common emitter circuit.

An isolating capacitor (12) connected to the secondary winding of the transformer (2) is connected to the input of the rectifier (4) with multiplying the photocathode voltage, and the output is connected to a voltage divider, which includes a resistor (13) and an adjustment element (9) and through a circuit ( 10) protection from bright sources to the output of the photocathode of the electron-optical converter.

The terminals of the variable resistor (11) are connected to the controller (6) for voltage control.

The claimed device operates as follows.

The high-voltage source of static voltage of the image intensifier converts the electric voltage of the direct current source (galvanic cell) into three high-voltage voltages to ensure the operation of the vacuum tube with microchannel amplification. To operate the vacuum tube of the image intensifier, an anode (screen) voltage, a voltage for the microchannel plate, and a voltage for powering the photocathode are required.

The generator (1), which is powered by a galvanic cell, creates harmonic oscillations in the primary winding of the transformer (2). The induced currents in the secondary winding of the transformer (2) are fed simultaneously to the rectifiers (3), (4), (5) with the multiplication of the voltage of the microchannel plate, photocathode and screen, respectively. The microchannel plate voltage is controlled by a controller (6) to control the voltage through an optocoupler (7). Voltage regulation is carried out by a variable resistor (11).

The power supply of the rectifier (5) with the multiplication of the screen voltage is carried out through the automatic brightness control circuit (8), which stabilizes the screen current through the control of the controller (6).

The power supply of the rectifier (4) with multiplying the voltage of the photocathode (4) is carried out through the blocking capacitor (12). Further, the rectified voltage is fed to a voltage divider, which consists of an adjusting element (9) and a resistor (13).

When using a bipolar high voltage transistor, a bias current resistor (14) is provided in the circuit. The voltage regulation of the photocathode is carried out by shunting the base-emitter junction of the adjusting element (9) with a trimming resistor (15). Further, the voltage of the photocathode from the adjusting element (9), through the circuit (10) for protection from bright sources, is connected to the electrode of the vacuum tube of the electron-optical converter.

The claimed device can be used in a high-voltage source of static voltage for electro-optical converters of the 2nd and 3rd generations.

The presented figures, the description of the design and use do not exhaust the possible variants of execution and do not in any way limit the scope of the proposed technical solution. Other variants of execution and use are possible within the scope of the claimed formula.

Claims (1)

High-voltage source of static voltage for the image converter, including a generator, the output of which is connected to the primary winding of the transformer, a rectifier with voltage multiplication of the microchannel plate connected to the controller for voltage control, including an output for connecting to the output of the microchannel plate of the image converter, a rectifier with by multiplying the screen voltage, connected to the automatic brightness control circuit, which includes an output for connecting to the screen output of the electro-optical converter, and a photocathode voltage multiplying rectifier configured to be connected to the photocathode output of the electro-optical converter, characterized in that the transformer is based on one secondary winding, to the output of which the inputs of the rectifiers with the voltage multiplication of the microchannel plate, the photocathode and the screen are connected, the rectifier with the voltage multiplication of the microchannel plate is connected it is connected to the controller for controlling the voltage through the optocoupler, while the terminals of the variable resistor are connected to the controller for controlling the voltage, the rectifier with multiplying the voltage of the photocathode is adjustable, while a decoupling capacitor connected to the secondary winding of the transformer is connected to the input of the rectifier with multiplying the voltage of the photocathode, and the output is connected to a voltage divider, which includes a resistor and an adjusting element, and through a protection circuit against bright sources to the output of the photocathode of the image converter.

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